Two shot injection molded vehicle hitch step

ABSTRACT

A hitch step assembly comprises a first shot component injection molded from a first polymer compound with a high flexural modulus and a second shot component injection molded from a second polymer compound having a lower flexural modulus relative to the first shot compound. A post and a step body core are molded from the first polymer compound. A shell of the step body is molded from the second polymer compound and is overmolded onto the step body core. The shell forms a compression zone that attenuates rear impact forces the hitch step encounters, thus offering some protection against rear impacts. The hitch step assembly exhibits satisfactory resistance to deflection and torsional bending about a hitch receiver axis when a force is applied on the top surface of the hitch step near its lateral ends.

RELATED APPLICATIONS

This application is a continuation of co-pending U.S. patent application Ser. No. 15/334,544 filed Oct. 26, 2016. The foregoing patent application is owned by a common assignee hereof and the disclosure and drawings of the foregoing application are fully incorporated by reference herein.

BACKGROUND OF THE INVENTION

Vehicles often have trailer hitch receivers mounted to the frame of the vehicle. These receivers are commonly rearward-facing and have an opening that accepts trailer hitch ball mounts, bike racks, cargo carriers and other hitch mounted accessories. One such accessory, a hitch step, provides a raised platform making the bed of a truck or the roof of a van or SUV more accessible. However, the location of a rearward-facing hitch step means that it is often the point of first impact during a rear end collision.

Because many light trucks, vans and SUV's have wide bodies, it is useful for a hitch step to have a wider, stable platform upon which a user may step at a considerable distance from the hitch axis. A need also exists for a hitch step that absorbs force from the impact of a rear collision along a greater transverse range to better protect more of the vehicle rear bumper.

Prior hitch steps are formed of metal, usually steel in order to withstand the weight of an adult at an off-axis position without unacceptable torsion around the hitch axis or cantilever deformation. Prior hitch steps therefore add considerable weight to the vehicle, and their ability to absorb, rather than transmit, impacts from the rear of the vehicle is limited.

The Applicant has previously developed an all-polymer trailer hitch step, as disclosed in U.S. Pat. No. 9,145,035 B2. While this trailer hitch step provides some protection against rear impacts and affords an area on which a user may step, the width of this hitch step is limited because of the torsional deformation and vertical deflection that would otherwise occur if a heavy load were placed on its transverse end.

SUMMARY OF THE INVENTION

According to one aspect of the invention, a hitch step assembly is made from a first shot component molded from a polymer having a flexural modulus of at least 300,000 psi at 23° C. and a second shot component overmolded onto the first shot component. The second shot component is formed of a thermoplastic elastomer having a bonding affinity to the first shot component and having a Shore D hardness of no more than 45 at 23° C. The assembly has a post formed from the first shot component and adapted to be inserted in a forward direction into a trailer hitch receiver. A step body of the assembly has a core integrally molded with the post, and forming a portion of the first shot component. A shell of the step body is formed of the second shot component and to be overmolded on at least a rear surface of the step body core. A compression zone of the shell extends rearwardly from the rear surface of the core and includes the rear wall of the step body. The compression zone includes plural spaced-apart ribs that extend rearwardly from the rear wall of the step body.

According to another aspect of the invention, a hitch step assembly is made from a first shot component and a second shot component overmolded onto the first shot component. The first shot component is molded from a polymer having a flexural modulus of at least 300,000 psi at 23° C. The second shot component is molded from a thermoplastic elastomer having bonding affinity as herein defined, to the first shot component and having a Shore D hardness of no more than 45 at 23° C. A post of the assembly is formed from the first shot component and is adapted to be inserted in a forward direction into a trailer hitch receiver. A step body of the assembly adjoins the post. The step body has a core integrally molded with the post, and forming a portion of the first shot component. A shell of the step body is formed of the second shot component and is overmolded at least on a rear surface of the step body core. The step body has a width in a transverse direction of more than 10.7 inches as measured from the post axis. When a load of 300 pounds (a weight selected to be more than most prospective users) is applied to the upper surface of the step body at a distance in the transverse direction of 10.7 inches from the post axis, the load will deflect the upper surface of the step body by no more than 1 inch.

According to another aspect of the invention, a hitch step assembly is made from a first shot component and a second shot component overmolded onto the first shot component. The first shot component is molded from a polymer compound exhibiting an inherent resistance to flexural deformation. The second shot component molded from a thermoplastic polymer having an affinity for bonding to the first shot component and exhibiting a substantially lower inherent resistance to flexural deformation relative to that of the first shot component. The hitch step assembly having a post that forms a first portion of the first shot component and is adapted to be inserted in a forward or x direction into a trailer hitch receiver. The assembly also including a step body that is elongated in a y direction, perpendicular to the x direction, and comprising a core that is integrally joined to and molded with the post and forms a second portion of the first shot component. The assembly also including a shell of the step body that is formed of the second shot component and overmolded onto at least a rear surface of the step body core. A rear panel wall of the shell to be spaced from the rear surface of the core to form a compression zone that extends rearwardly from the rear surface of the core and is delimited by the rear panel wall of the shell. The compression zone for attenuating forces that impact against the rear panel wall of the shell.

According to still another aspect of the invention, a hitch step assembly is adapted to be inserted within a receiver in a forward direction thereto, with the receiver having a central axis running in the forward direction, the assembly made from a first shot component and a second shot component overmolded onto the first shot component. The first shot component molded from a polymer compound having an inherent resistance to flexural deformation. The second shot component overmolded onto the first shot component and formed from a thermoplastic elastomer having an affinity for bonding to the first shot component and exhibiting an inherent flexural deformation that is substantially lower relative to that of the first shot polymer compound. The assembly includes a post formed from the first shot component and having a central x axis corresponding with the central axis of the receiver. The assembly also including a step body formed from the first shot component and having an upper surface, a rear surface and a y axis that is transverse to and on a same plane as the x axis, the step body delimited by a width extending along the y axis and centered relative to the x axis, the step body comprising a core integrally molded to the post through a throat region extending therebetween, the core having a center located at the intersection of the x and y axes, the core being substantially hollow and divided into four quadrants in the xy plane around the center, each quadrant configured with a plurality of stiffening plates. The assembly also including a shell formed of the second shot component and overmolded at least onto the rear surface of the core, the shell being more elastically deformable than the core and including a rear panel wall spaced from the rear surface of the core. The core of the step body and the post being configured to cooperatively limit an extent of flexural twisting and downward deflection which the hitch step assembly experiences when a load force is placed upon the upper surface of the step body, with the extent of flexural twisting and downward deflection progressively decreasing as the load force is applied in a direction closer to the post.

The present invention thus provides a polymer trailer hitch step that is wider in a transverse direction than prior polymer hitch steps, but which still is acceptably resistant to torsional force around the post axis and to downward deflection by a large load placed near an end of the step body. The second-shot compression zone of the disclosed hitch step provides a modicum of protection from rear impacts without irreversible damage to either the hitch step or to the vehicle to which it is mounted. The wider aspect of the disclosed hitch step affords increased protection of a rear vehicle bumper from rear impacts and expands the locations where a user can place his or her foot in gaining access to the upper reaches of the vehicle. The second shot top tread surface of a lower durometer material can also provide a higher friction surface under foot when standing on the step.

BRIEF DESCRIPTION OF THE DRAWINGS

Further aspects of the invention and their advantages can be discerned in the following detailed description, in which like characters denote like parts and in which:

FIG. 1 is an isometric upper rear view of one embodiment of a hitch step assembly according to the invention;

FIG. 2 is an upper left front isometric exploded view of one embodiment of a hitch step assembly, illustrating a portion of a trailer hitch receiver, bolt, washers and nut;

FIG. 3 is an upper right front isometric exploded view of the embodiment shown in FIG. 2;

FIG. 4 is a left side view of one embodiment of the invention;

FIG. 5 is a right side view of the embodiment shown in FIG. 4;

FIG. 5A is a sectional view taken substantially along line 5A-5A of FIG. 5;

FIG. 6 is a bottom left isometric view of one embodiment of the invention;

FIG. 7 is a bottom horizontal sectional view taken in the plane of the post and step body of one embodiment of the invention;

FIG. 8 is a bottom view of one embodiment of the invention;

FIG. 9 is a sectional view taken substantially along line 9-9 of FIG. 8;

FIG. 10 is a sectional view taken substantially along line 10-10 of FIG. 8;

FIG. 11 is a sectional view taken substantially along line 11-11 of FIG. 8; and

FIG. 12 is a rear view, with a dotted line illustrating the position of the step body under a 300 pound load placed at a distance w₁ on the top surface of one embodiment of the invention.

DETAILED DESCRIPTION

The present invention provides a hitch step for insertion into a hollow receiver type hitch on a vehicle. In the embodiment shown in FIG. 1, a hitch step, generally indicated at 100, includes a step body 102 and a post 104. Hitch step 100 is formed by injection molding in a two-shot process. The post 104 is formed from a first shot component molded from a polymer having a flexural modulus of at least 300,000 psi at 23° C. The polymeric compound generally has a high impact strength, ideally one that is rated as “No-Break” at 23° C. according to the Charpy Unnotched impact test criteria. All properties listed are for an ambient temperatures of 23° C. unless otherwise noted. The material can be a thermoplastic polyester blended with a thermoplastic polycarbonate. In one embodiment the first shot component is a polycarbonate (PC)/polybutylene terephthalate (PBT) polyester blend that has a flexural modulus of 305,000 psi at 23° C. and an impact strength of NB at 23° C. Key properties of the first shot component appear in the following table:

TABLE 1 Test Method Value Property Flexural Modulus @23° C. ISO 178 305,000 psi Hardness, Ball Indentation ISO 2039-1  14,500 psi Charpy Unnotched Impact strength: −30° C. ISO 179/IeU No Break   23° C. ISO 179/IeU No Break Charpy Notched Impact strength: −30° C. ISO 179/IeA    21 ft-lb/in{circumflex over ( )}2   23° C. ISO 179/IeA    29 ft-lb/in{circumflex over ( )}2

There are several alternative polymers that can be used for the first shot component, but may exhibit lesser performance attributes than those set forth above. Higher flexural modulus in plastics is typically associated with materials that are more brittle in nature, and conversely materials that exhibit excellent impact resistance and toughness are typically associated with lower flexural modulus materials. The preferred PC/PBT polymer blend maintains both a high flexural modulus and high impact resistance, and is therefore ideally suited for this application where step stability is important as well as resistance to breakage upon low level vehicle impact. Other materials may be chosen, but some of the performance attributes may be diminished. For instance, acrylonitrile butadiene (ABS), polystyrene, PBT polyester, reinforced polypropylene (PP) or even nylon may have sufficiently high flexural moduli, but may fail upon impact or worse yet may fail (break) when a heavy individual is standing on the step. High density polyethylene (HDPE), toughened polypropylene, stiffer grades of Hytrel® (a range of thermoplastic elastomer compounds from DuPont™), or other similar high impact materials may offer good resistance to breakage, but in the present structural design these materials would not offer necessary stability when a heavy individual is standing on the step—the step may bend or torsionally twist at the step/post region and the individual may feel unsafe on the step or worse yet may fall off the step if it flexes or twists sufficiently to cause the person to slip. Temperature extremes must also be taken into consideration. Some materials may either experience flexural strength loss at elevated temperatures (for example, 120° F. in the hot Arizona sun) as would be the case with the HDPE, PP, or Hytrel®—these materials would exhibit even more flex and instability at higher temperatures. At the cold extreme (for example −25° F. in Minnesota), some materials may exhibit cold embrittlement and would have a higher likelihood of breakage upon low level impact, or breakage when an individual stands on the step. The PC/PBT blend material exhibits both high flexural modulus at temperature extremes and excellent cold temperature impact strength and again is ideally suited as the first component material. To a lesser degree, polycarbonate itself may provide properties similar to the PC/PBT blend, but does not exhibit as good a cold temperature impact strength that the PC/PBT exhibits.

The step body 102 has two parts: a core 622 (see FIGS. 6-8) that is integrally molded with the post 104, and a shell 108 overmolded onto the core 622 to form most of a body exterior surface 109. The shell 108 is formed in a second shot part of the injection molding process. The shell 108 extends rearwardly and downwardly over the step body core 622. Preferably the shell 108 forms a rear panel 106 of the step body 102 and also makes up the exterior the side panels or walls 114, 164 (FIG. 2) of the step body 102.

The second shot component is made from a polyester based thermoplastic elastomer having a hardness of about 40 to about 50. The second shot component has a bonding affinity to the first shot component when overmolded. Ideally, the second shot material when overmolded to the first shot component will provide a cohesive bond. In this regard, there is a chemical coupling between the two materials, and the two materials will not delaminate. For the purpose of this application “Bonding affinity” means that when placed under a peel test, the failure mode would be a tearing of one of the materials itself, instead of peeling apart one material from the other. In other words, there will be a cohesive failure not an adhesive failure.

This type of cohesive bond is achieved when the chemistry between first shot material and overmold material have such compatibility as to achieve bonding at the molecular level. In the case of the present design, a copolyester based thermoplastic elastomer (TPE) is chosen for the second component material that has a particularly good chemical bonding affinity to the PC/PBT first component material. The copolyester based TPE in the 40 to 50 Shore D durometer range also exhibits a high degree of elasticity both at lower and higher temperatures. If another first component material were chosen, such as polypropylene, then a different second component material may be chosen (such as styrene ethylene butylene styrene (SEBS) TPE that may again provide cohesive bonding to the first component material. Alternatively, if the second component TPE did not have a bonding affinity to the first component material, a mechanically interlocking design may be used, as seen for example in U.S. Pat. No. 9,248,783 B2, owned by the assignee hereof and incorporated herein by reference.

Key properties an exemplary second shot component appear in Table 2 below.

TABLE 2 Property Test Method Value Hardness, Shore D ISO 868 ≤45 Flexural Modulus @23° C. ISO 178 ≤12,600 psi Tensile Modulus @23° C. ISO 527-1/-2 ≤12,300 psi Nominal Strain at Break ISO 527-1/-2 740% Tear Strength Parallel ISO 34-1 method B/a   697 lb/in Tear Strength Normal ISO 34-1 method B/a   703 lb/in

A top surface 118 of the step body 102 is formed when the second shot component is overmolded onto the first shot component. The top surface 118 can have grooves or a tread pattern 119. One property of the second shot component is that it can provide enhanced traction and a softer grip of the top surface 118 of the step body 102.

In the embodiment shown in FIG. 1, the step body 102 is arranged along a y axis that is transverse, horizontal and perpendicular to the x axis. The post 104 is adapted to be inserted, in a forward direction or longitudinally along the x axis, into a trailer hitch receiver 200 as shown in FIG. 2. In one embodiment of the invention, the step body 102 has a width in they direction that is greater than 10.7 inches from the center of the axis, such as 12 inches. The rear panel 106 is roughly perpendicular to the longitudinal x axis although preferably is slightly rearwardly and downwardly sloped from the top surface 118 (see FIGS. 4 and 5). The rear panel 106 may be flat but is preferably is rearwardly convexly curved relative to a yz plane, z being vertical. It is curved in such a way that in the event of a collision from the rear along the x axis, the center of rear panel 106 would be the first part to be hit. The rear panel 106 may be taller in a z direction at the x axis than it is at a transverse distance from the x axis, and may have a convexly curved or sloped lower margin as shown.

In the embodiments shown in FIGS. 2-3, the hitch step 100 has a transition area between the post 104 and the step body 102, so as to form a throat region 201. The throat region 201 is chamfered, sloping downward or inward from a front wall 203 of the step body 102 to the top surface or sides 122, 123, 125 of the post 104. The chamfered and radiused design reduces stress concentration at the post/body connection points. The throat region 201 includes a top plate 205 that slopes forwardly and downwardly from rear panel 106 to post top surface 122, a left side wall 207 that slopes forwardly and toward the x axis until its junction with left post side 123, and a right side wall 209 that slopes forwardly and toward the x axis until it joins with right post side 125.

Still referring to FIGS. 2-3, and moving toward the front end 124 of the post and away from the throat region 201, four bolt holes 116 are shown. As seen in FIG. 2, the left ends 502 of the bolt holes 116 take the form of multi-sided prisms, one of which will be selected to receive a nut 204. In the illustrated embodiment the nut 204 is a hex nut and the prisms are hexagonal. As shown in FIG. 7, The bolt 202 is inserted into a lock washer 208, a flat washer 206, a hole 700 in a left side 702 of the square-shaped hitch receiver 200 and a selected one of the four bolt holes 116, and is then threaded into a hex nut 204 that had been inserted into a left end 502 of the selected bolt hole 116.

FIG. 5A is a cross sectional view of post 104, showing one embodiment of the nut receiver 502 and associated bolt hole 116. The hexagonal openings on left side 123 of the post 104 are opposite circular openings on the right side 125 of the post 104 to allow bolt 202 to pass through to nut 204. After tightening, and as seen in FIG. 7, the nut 204 is compressed against a solid cylindrical structure 504 and against the wall 702 of the hitch receiver 200. The hitch receiver hole 700 and bolt 202 are essentially the only attachment point holding the hitch step 100 to the trailer hitch receiver 200. Generally the nut and bolt can be any nut and bolt that is fairly substantial in size. Although not limited to any particular size, one embodiment uses a ⅝″ bolt thread, 15/16″ across the flats of the nut. The bolt can be tightened substantially due to the high compressive strength of the PC/PBT. The use of the PC/PBT material allows such an attachment as the material is not as subject to plastic deformation as softer more compressible materials would be. The outer right side of the post 104 is drawn firmly against the inner right side wall 702 of the hitch receiver 200. The tightness of installation mitigates any looseness that would otherwise be experienced for if using for example, a through pin attachment that requires some clearances for assembly of the pin. The looseness, particularly in a 24″ wide step, could be perceived as an unstable state by someone standing on the step, so this attachment method is more appropriate for this design given the width of the step

In the embodiments shown in FIGS. 6-8, the underside of step body 102 and throat region 201 are substantially hollow so that that the body 102 and throat region 201 may be fabricated through injection molding without significant departures from a nominal wall thickness. It can be seen in FIG. 6 that the post 104 is integrally formed in the same injection molding shot as the body core 622. The post 104 is formed along the x axis and is square in axial cross-section as seen in FIGS. 2, 3 and 5A. In one embodiment, the post 104 may be about two inches wide and tall, to fit a popular size of trailer hitch receiver 200. The right transitional wall 209 of throat region 201 is formed at an angle to the x and y directions and extends from the right side 125 of post 104 to intersect and extend rearwardly beyond the front wall 626 of the core 622 and to terminate at a transversely oriented center wall 630. A left transitional wall 207 is formed at an angle to the x and y directions and extends from the left side 123 of post 104 to intersect and extend rearwardly beyond the front wall 626 of the core 622, and to terminate at the core center wall 630. The core 622 is bounded by and includes the core front wall 626, a left side core wall 614, a right side core wall 628 and a rear core wall 634. In the illustrated embodiment, the external surfaces of core walls 626, 614, 628 and 634 are respectively overmolded with walls 203, 704, 706 and 708 of the second-shot shell 108, covering all of the core 622 except for its bottom and the location where throat region 201 and post 104 extend forwardly from the core 622.

As seen in FIG. 7, the core 622 has a left front quadrant 601, a left rear quadrant 602, a right rear quadrant 603, and a right front quadrant 604. The core center wall 630 has a midpoint or core center 624, runs along they axis of the step body 102, is aligned to the vertical or z axis, and separates the front quadrants 601, 604 from the rear quadrants 602, 603. Each quadrant 601-604 has at least one but preferably a plurality of spaced-apart slanted plates 618, each of which is aligned to the vertical or z direction. The slanted plates 618 in each quadrant 601, 602, 603, 604 are parallel to each other, each quadrant being a mirror image of an adjacent quadrant.

In the embodiment show in FIGS. 6-8, plates 618 and center wall 630 form a herringbone pattern. Each of the slanted plates 618 has a medial or central end, joined to center wall 630, that is displaced in a transverse direction from center 624 more than its opposed, lateral end. The central ends further each terminate at a point on center wall 630 that is shared by a central end of an adjacent slanted plate 618. This herringbone pattern may allow some degree of bending in the xy plane in the event of an offset impact in the rear, but nevertheless provides bending strength and rigidity in the y direction.

As shown in FIGS. 6-8, center 624 is disposed at the intersection of the x and y axes of the device. Certain walls of the core 622 form a plurality of triangular prisms 710-720 each having one apex at center 624, and each triangular prism 710-720 has two plates or walls in common with the neighboring triangular prisms 710-720.

Right front prism 710 is constituted by center wall 630, throat region wall 209 and a wall 722 that extends from center 624 about to the junction of wall 209 and post side 125. Center front prism 712 is constituted by wall 722, a front wall 724 of the throat region 201, and a wall 726 that extends from center 624 about to the junction of wall 207 and post side 123. Left front prism 714 is constituted by wall 726, throat region wall 207 and step body center wall 630. Left rear prism 716 is constituted by a wall 728 that extends from a junction of wall 207 and wall 630 rearwardly and transversely inwardly to rear core wall 634. Center rear prism 718 is constituted by a wall 730 that extends from center 624 leftwardly and rearwardly to rear core wall 634, rear core wall 634, and a wall 732 that extends from center 624 rearwardly and rightwardly to the rear core wall 634. Right rear prism 720 is constituted by wall 732, a wall 734 that extends from the junction of throat region wall 209 and center wall 630 to a junction of wall 732 and rear core wall 634, and core center wall 630. Prisms 710-720 extend into the throat region 201 and provide more local stiffness and torsional strength in the throat region 201.

The second shot is overmolded onto a top wall 900 (see FIGS. 9-11) of the core 622 and preferably also is overmolded onto the side walls 614, 628 and rear wall 634 of the core 622. Second shot walls 704, 706 and 708 form an inner boundary of a compression zone 600. Compression zone 600 extends rearwardly from wall 708 to include rear wall 106 of the step body 102. Compression zone 600 further and preferably extends rightward (to the left in the bottom views of FIGS. 6-8) from wall 706 to outer wall 114, and leftward (to the right in FIGS. 6-8) from wall 704 to include outer wall 164. The assembly can withstand impact from a 4,000 pound vehicle moving at a speed of no more than five miles per hour.

Preferably compression zone 600 contains several spaced-apart ribs 610. Each rib 610 has a first rib end 611 is attached to the outer wall 106 of the step body 102, and a second rib end 612 that is closer to the core rear surface 608. In one embodiment each rib 610 is attached at its second rib end 612 to inner compression zone wall 708. It is preferable that the ribs 610 be arcuate between their ends 611, 612. This arcuate cross section will promote collapsing in the event of a rear impact, but the resilient nature of the thermoplastic elastomer making up ribs 610 will allow the compression zone 600 to spring back to its original shape after sustaining a modest impact. This adds additional protection the vehicle in the event of a rear collision.

In the illustrated embodiment, the compression zone 600 has a right side region 736 that includes walls 706 and 114, and a left side region 738 that includes walls 704 and 164. Right side region 736 includes at least one arcuate rib 740 that extends between wall 706 and wall 114. Left side region 738 includes at least one arcuate rib 742 that extends between wall 704 and wall 164. Ribs 740 and 742 give a measure of elastic compression in response to impacts having vectors at a considerable angle to the x axis.

The shell 108 also overmolds the core front wall 626 with a front wall 203. In the event of a collision that is so severe that the step body 102 deflects forwardly to impact a rear bumper of the vehicle (not shown), the elastomeric front wall 203 will provide some cushioning and some protection against marring the bumper surface, which in recent vehicles tends to be flexible painted plastic.

As seen in FIGS. 8-11, core wall 900 is of a substantially uniform thickness to aid in injection molding the part.

As shown in FIG. 10, the post 104 has a central vertical plate 1000 aligned on the x axis to extend downward from top wall 122 and extending for the entire length of post 104. Plate 1000 forms the inner boundary of each nut receiver 502. The sections shown in FIGS. 9 and 11 depict inclined reinforcing plates 902 that intersect each other at the x axis, are disposed at an angle to the z axis, and provide additional stiffness.

The two-shot construction of hitch step 100 permits it to enjoy the advantages of a relatively stiff step body core 102 and a shell 108 that springs back from a modest amount of impact force and exhibits a good coefficient of friction. In one embodiment, if a load representing a relatively large user is placed at point 1200 as shown in FIG. 12, where point 1200 is w₁ from the z axis, the top surface 118 of the step body 102 will only deflect by a deflection d. In one embodiment, in which a load of 300 pounds is placed on surface 118 at 10.7 inches from the z axis, deflection d will be no more than about one inch. A load of 300 pounds was selected to emulate the weight of a large man. In this embodiment, the entire width of the step body in ay direction is about 12 inches, providing a greater amount of coverage to a vehicle's rear bumper and affording an extended range of locations where a user may place his or her foot.

In summary, an all-polymer trailer hitch step has been provided in which a first shot component makes up a core of the step body and the post, and a second-shot component makes up a step body shell. The first shot component is sufficiently stiff that a transverse width of the step body may be outwardly extended beyond dimensions previously unattained by nonmetallic hitch step structures. At the same time, the second-shot component provides an elastically deformable compression zone that can absorb a modest amount of rear impacts without failure, and protects an extended portion of a vehicle's rear bumper. While illustrated embodiments of the present invention have been described and illustrated in the appended drawings, the present invention is not limited thereto but only by the scope and spirit of the appended claims. 

We claim:
 1. A hitch step assembly comprising: a first shot component molded from a polymer compound that exhibits an inherent resistance to flexural deformation; a second shot component overmolded onto the first shot component, the second shot component formed from an thermoplastic elastomer having an affinity for bonding to the first shot component and which exhibits an substantially lower inherent resistance to flexural deformation relative to that of said first shot component; a post forming a first portion of the first shot component and adapted to be inserted in a forward direction into a trailer hitch receiver, the post oriented in an x direction; a step body elongated in a y direction at a right angle to the x direction and joined to the post, said step body comprising: a core integrally molded with the post, the core forming a second portion of the first shot component and having a rear wall with a rear surface; a shell of the step body formed of the second shot component, wherein the shell of the step body is overmolded at least onto the rear surface of the core, a rear panel wall of the shell formed from the second shot component to be spaced from the rear surface of the core, a compression zone of the shell extending rearwardly from the rear surface of the core and delimited by the rear panel wall of the shell, said compression zone attenuating a force that results from an object impacting against the rear panel wall.
 2. The hitch step assembly of claim 1, wherein the first shot component additionally exhibits an inherent resistance to impact stresses and said second shot component exhibits a lower inherent resistance to impact stresses relative to that of said first shot component.
 3. The hitch step assembly of claim 1, wherein first shot component exhibits a flexural modulus that is at least 20 times greater than the flexural modulus of the second shot component and no higher than 30 times greater.
 4. The hitch step assembly of claim 1, wherein said affinity for bonding of the second shot component to said first shot component is through a chemical bond in which said first and said second components will not adhesively delaminate from each other prior to one of said first or second shot components cohesively failing by tearing.
 5. The hitch step assembly of claim 1, wherein the shell is mechanically attached to said core.
 6. The hitch step assembly of claim 1, wherein polymer compound of the first shot component comprises a polycarbonate/polybutylene terephthalate polyester blend and said second shot component comprises a polyester based thermoplastic.
 7. The hitch step assembly of claim 1, wherein the core includes a front wall spaced from said rear wall and extending between said left and right walls and said post includes a centrally disposed vertical plate extending a length of said post, and wherein said post is adjoined to the core by a throat region, whereby said plate and said throat region cooperate to decrease the propensity of the step assembly to axially twist in a direction along the post and to deflect in a vertical direction.
 8. A hitch step assembly adapted to be inserted within a receiver in a forward direction thereto, said receiver having a central axis running in said forward direction, said assembly comprising: a first shot component molded from a polymer compound having an inherent resistance to flexural deformation; a second shot component overmolded onto the first shot component, the second shot component formed from an thermoplastic elastomer having an affinity for bonding to the first shot component and exhibiting an inherent flexural deformation that is substantially lower relative to that of said first shot polymer compound; a post formed from the first shot component and having a central x axis corresponding with said central axis of said receiver; and a step body formed from the first shot component and having an upper surface, a rear surface and a y axis that is transverse to and on a same plane as said x axis, said step body delimited by a width extending along said y axis and centered relative to said x axis, said step body comprising: a core integrally molded to the post through a throat region extending therebetween, said core having a center located at the intersection of the x and y axes, the core being substantially hollow and divided into four quadrants in the xy plane around the center, each quadrant configured with a plurality of stiffening plates; a shell formed of the second shot component and overmolded at least onto the rear surface of the core, a rear panel wall of the shell to be spaced from the rear surface of the core, said shell more elastically deformable than said core, wherein said core of said step body and said post are configured to cooperatively limit an extent of flexural twisting and downward deflection which said hitch step assembly experiences when a load force is placed upon said upper surface of said step body, the extent of flexural twisting and downward deflection progressively decreasing as the load force is applied in a direction closer to said post.
 9. The hitch step assembly of claim 8, wherein the post includes a centrally disposed vertical plate extending a length of said post, said plate further strengthening said post from deflecting in a vertical direction.
 10. The hitch step assembly of claim 8, wherein said throat region includes a right transitional wall extending from a right side of the post to the rear wall of the core and a left transitional wall extending from a left side of the post to the rear wall of the core, said transitional walls strengthening said hitch step assembly from flexural twisting in an axial direction relative to said x axis and against vertical deflection.
 11. The hitch step assembly of claim 8 wherein the core has a front wall substantially oriented in a yz plane, a rear wall of the core spaced from the front wall of the core, a center wall of the core substantially oriented in a yz plane and spaced between the front wall of the core and the rear wall of the core, each of the plates within each quadrant having a first end and a second end opposed to said first end, wherein one end of each plate is connected to said center wall and the other end of each plate is connected to one of said front or rear walls.
 12. The hitch step assembly of claim 8, wherein said the space between said rear panel wall of said shell and said rear surface of said core forms an zone for attenuating impact forces that contact against the rear panel wall. 